Method for measuring human body aura and system therefor

ABSTRACT

The system for measuring aura of a human body according to the present invention includes: an aura sensing part  1  to be contacted to a human body, for measuring the physiological signals of the human body; and a data processing system  2  for processing the aura data of the physiological signals. Further, the aura sensing part according to the present invention includes a left hand measuring sensor  100  and a right hand measuring sensor  200,  to be contacted to the palms of the human body. The left hand measuring sensor  100  according to the present invention includes: a thumb sensor  105,  a first finger sensor  104,  a second finger sensor  103,  a third finger sensor  102,  a fourth finger sensor  101,  an upper palm sensor  106,  an intermediate palm sensor  107  and a lower palm sensor  108,  for measuring the physiological signals radiating from the fingers and palm. The right hand measuring sensor  200  according to the present invention includes: a thumb sensor  201,  a first finger sensor  202,  a second finger sensor  203,  a third finger sensor  204,  a fourth finger sensor  205,  an upper palm sensor  206,  an intermediate palm sensor  207  and a lower palm sensor  208,  for measuring the physiological signals radiating from the fingers and palm. The data processing system  2  according to the present invention includes: a computer  21  for processing the obtained data; a monitor  22  and/or a printer  23  for outputting the processed data; and a camera  24  for photographing the person as a test object.

FIELD OF THE INVENTION

[0001] The present invention relates to a system for measuring humanbody aura. More specifically, the present invention relates to a systemfor measuring human body aura, in which physiological signals of palms,foot soles and fingers due to temperature, blood flow, heart pulse,electrodermatography, electromyography and the like can be sensed, andthe sensed data can be analyzed by a computer, so that the internalenergy state of a person as a test object can be displayed in a monitoror an LCD panel, thereby making it possible to visually confirm thesymptom of the person. Further, the present invention relates to amethod for measuring a human body aura.

BACKGROUND OF THE INVENTION

[0002] Recently, the oriental conception “Gi” (power state) isfrequently talked in everyday life. The words related to the power stateare numerous including “the feeling is good”, “the feeling is absolutelyobstructed”, “the spirit is down”, “high spirited”, “exhausted”,“absolutely exhausted”, “dominatingly spirited”, “popular and esteemed”,and the like.

[0003] This is a power state or an energy state. The power state has nosize, shape, weight or odor, but it is the motive force for moving thehuman body. The power state is transmitted in the form of sound, lightand other waves.

[0004] The power state of human body can be classified into motivepower, general power, and true power. The motive power is that which hasbeen innately gifted, and the general power is based on the energy whichis obtained from the oxidation of the ingested food to use it ineveryday life.

[0005] The true power can be obtained through the concentration ofspirit. That is, it can be obtained through a long term training. Thetrue power can be adjusted by mind, and the power state of this kind isvaried depending on the state of mind.

[0006] In 1939, Kirlian who was a Russian electrician showed a powerstate photograph through a machine which had been invented by him. Thephotograph was presented to an audience which consisted of eminentscientists. The photograph showed the bio-energy which was radiated fromthe human body, and this is called “Kirlian photograph”.

[0007] A scientist brought two leaves of a plant to Kirlian, and askedhim to photograph them. When the leaves were photographed, the resultwas that one of them showed a clear and definite color, and the othershowed only a fading color.

[0008] The reason was that the latter leaf was that which was infectedto an illness. In this occasion, Kirlian said that a biological entityhas two aspects, and one of them is the visible physical body, while theother is an energy entity (a second body) which can be confirmed only bya photograph.

[0009] This theory can be applied also to the human body. If this can beapplied to the medical science, then a drastic result can be obtained,because then any illness can be diagnosed in advance.

[0010] This is meant that if the power state of the human body can beconfirmed visually, then it will become a medically useful means.

[0011] Kendal Johnson of the United States carried out a research on theKirlian photograph. He elucidated the following facts. That is, adefinite aura can be observed in a human body which has been loosened bymeditation.

[0012] Further, if a critical point of human body is stimulated, thenthe aura radiation is increased around the fingers. Further, a patientwho received a power state treatment showed a more definite brighteraura than he who has not been treated.

[0013] The resonance magnetic analyzer which is being developedcurrently in the United States can diagnose the disordered part of theinternal organs by detecting the waves which are radiated from therelevant organ.

[0014] The U.S. physician Dr. Albert Abrahms found that not only thedifferent organs of human body radiate different kinds of waves, butalso the radiations from

[0015] bacteria of various illness are of different kinds.

[0016] As described above, the power state which is the spiritual andphysical status of the human body can be expressed by visual means suchas color and shape.

[0017] When a person as a test object mounts his or her palm on asensor, the physiological signals or thermal energy emanating therefromare not always same.

[0018] If the feeling of the tested person is not good, or if there isan abnormality such as stress, then the measured result will bedifferent from the normal person.

[0019] If one of parents or other close relatives has died, or if thebusiness has been failed, or if there is an excessive exhaustion, thenthe variation of the internal energy will be great.

[0020] If this internal energy state can be measured and visuallyconfirmed, then this means will be widely used to protect his or her ownhealth.

[0021] The photo-sensing polaroid camera is the conventional means whichcan measure the internal energy state of human body to provide avisually confirmable data.

[0022] That is, a person as a test object is photographed, and color andshape are formed to show the internal status of the test object.

[0023] However, the conventional polaroid camera is inconvenient tohandle it by a single person, the result cannot be obtained immediately,and the analysis cannot be carried out without being helped by aprofessional person.

[0024] In order to overcome the above described disadvantages of theconventional technique, the present inventors have invented a system inwhich the manipulation is easy, and the analysis of the result can becarried out even without an assistance of a professional person.

SUMMARY OF THE INVENTION

[0025] It is an object of the present invention to provide a system bywhich one's own internal energy state can be measured.

[0026] It is another object of the present invention to provide a systemin which the measured internal energy state can be confirmed by acomputer monitor or an LCD panel on a real time basis.

[0027] It is still another object of the present invention to provide asystem in which a person as a test object can analyze the image of hisor her own internal energy state even without a help of a professionalperson.

[0028] It is still another object of the present invention to provide asystem in which human body aura can be made formed on the figure of themeasured person at the measured time.

[0029] All the above objects and other objects can be accomplished bythe detailed descriptions presented below.

[0030] The system for measuring aura of a human body according to thepresent invention includes: an aura sensing part 1 to be contacted to ahuman body, for measuring the physiological signals of the human body;and a data processing system 2 for processing the aura data of thephysiological signals.

[0031] Further, the aura sensing part according to the present inventionincludes a left hand measuring sensor 100 and a right hand measuringsensor 200, to be contacted to the palms of the human body.

[0032] The left hand measuring sensor 100 according to the presentinvention includes: a thumb sensor 105, a first finger sensor 104, asecond finger sensor 103, a third finger sensor 102, a fourth fingersensor 101, an upper palm sensor 106, an intermediate palm sensor 107and a lower palm sensor 108, for measuring the physiological signalsradiating from the fingers and palm.

[0033] The right hand measuring sensor 200 according to the presentinvention includes: a thumb sensor 201, a first finger sensor 202, asecond finger sensor 203, a third finger sensor 204, a fourth fingersensor 205, an upper palm sensor 206, an intermediate palm sensor 207and a lower palm sensor 208, for measuring the physiological signalsradiating from the fingers and palm.

[0034] The data processing system 2 according to the present inventionincludes: a computer 21 for processing the obtained data; a monitor 22and/or a printer 23 for outputting the processed data; and a camera 24for photographing the person as a test object.

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] The above objects and other advantages of the present inventionwill become more apparent by describing in detail the preferredembodiments of the present invention with reference to the attacheddrawings, in which:

[0036]FIG. 1 is a block diagram showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention;

[0037]FIG. 2 is a frontal view showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention;

[0038]FIG. 3 is a side view showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention;

[0039]FIG. 4 is a flow chart showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention;

[0040]FIG. 5 is a flow chart showing the constitution of the measuringprocedure for the palm-contacting type human body aura measuring systemaccording to the present invention;

[0041]FIG. 6 is a block diagram showing the constitution of the footsole-contacting type human body aura measuring system in anotherembodiment of the present invention;

[0042]FIG. 7 is a block diagram showing the constitution of thetwo-finger contacting type human body aura measuring system in stillanother embodiment of the present invention;

[0043]FIG. 8 is a flow chart showing the constitution of the footsole-contacting type or two-finger-contacting type human body aurameasuring system according to the present invention; and

[0044]FIG. 9 is a flow chart showing the constitution of the measuringprocedure for the foot sole-contacting type or two-finger-contactingtype human body aura measuring system according to the presentinvention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0045] The preferred embodiments of the present invention will bedescribed in detail referring to the attached drawings.

[0046] The system for measuring the aura of the human body according tothe present invention includes: an aura sensing part 1 to be contactedto a human body, for measuring the physiological signals of the humanbody; and a data processing system 2 for processing the aura data of thephysiological signals. Further, the aura sensing part according to thepresent invention includes a left hand measuring sensor 100 and a righthand measuring sensor 200, to be contacted to the palms of the humanbody. The left hand measuring sensor 100 according to the presentinvention includes: a thumb sensor 105, a first finger sensor 104, asecond finger sensor 103, a third finger sensor 102, a fourth fingersensor 101, an upper palm sensor 106, an intermediate palm sensor 107and a lower palm sensor 108, for measuring the physiological signalsradiating from the fingers and palm. The right hand measuring sensor 200according to the present invention includes: a thumb sensor 201, a firstfinger sensor 202, a second finger sensor 203, a third finger sensor204, a fourth finger sensor 205, an upper palm sensor 206, anintermediate palm sensor 207 and a lower palm sensor 208, for measuringthe physiological signals radiating from the fingers and palm.

[0047] The data processing system 2 according to the present inventionincludes: a computer 21 for processing the obtained data; a monitor 22and/or a printer 23 for outputting the processed data; and a camera 24for photographing the person as a test object.

[0048]FIG. 1 is a block diagram showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention.

[0049] The system for measuring the aura of the human body according tothe present invention includes: an aura sensing part 1 to be contactedto a human body, for measuring the physiological signals of the humanbody; and a data processing system 2 for processing the aura data of thephysiological signals.

[0050] Further, the aura sensing part according to the present inventionincludes a left hand measuring sensor 100 and a right hand measuringsensor 200, to be contacted to the palms of the human body.

[0051] The left hand measuring sensor 100 according to the presentinvention includes: a thumb sensor 105, a first finger sensor 104, asecond finger sensor 103, a third finger sensor 102, a fourth fingersensor 101, an upper palm sensor 106, an intermediate palm sensor 107and a lower palm sensor 108, for measuring the physiological signalsradiating from the fingers and palm.

[0052] That is, the physiological signals of human hands due totemperature, blood flow, heart pulse, electrodermatography,electromyography and the like are accurately measured.

[0053] The right hand measuring sensor 200 according to the presentinvention includes: a thumb sensor 201, a first finger sensor 202, asecond finger sensor 203, a third finger sensor 204, a fourth fingersensor 205, an upper palm sensor 206, an intermediate palm sensor 207and a lower palm sensor 208, for measuring the physiological signalsradiating from the fingers and palm. That is, the physiological signalsof human hands due to temperature, blood flow, heart pulse,electrodermatography, electromyography and the like are accuratelymeasured.

[0054] The data processing system 2 analyzes the physiological signalsof the human palms obtained from the temperature, blood flow, heartpulse, electrodermatography, electromyography and the like. The resultis outputted to a monitor 22 or a printer 23, and in order to increasethe reality sensation of the outputted image, the person as a testobject is actually captured.

[0055] The data processing system 2 according to the present inventionincludes: a computer 21 for carrying out the overall control; a monitor22 and/or a printer 23 for outputting the processed data; and a camera24 for capturing the person as a test object.

[0056]FIG. 2 is a frontal view showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention. FIG. 3 is a side view showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention.

[0057] The reason why the human palm is contacted in measuring the humanbody aura is that the human palm is very sensitive compared with theother portions of the human body, and the emanation of aura isintensive.

[0058]FIG. 4 is a flow chart showing the constitution of thepalm-contacting type human body aura measuring system according to thepresent invention. FIG. 5 is a flow chart showing the constitution ofthe measuring procedure for the palm-contacting type human body aurameasuring system according to the present invention.

[0059] The aura measuring method in which the palm is contacted iscarried out in the following manner. That is, at first the person as atest object drives the computer, and selects one of the modes among acamera using mode and a camera non-using mode.

[0060] The camera-using mode is for capturing the real entity image ofthe test object after measuring the aura, so that a real sensation ofthe image can be obtained.

[0061] In the case where the camera-using mode is selected, themeasuring method is carried out in the following manner. That is, theperson as a test object selects the camera-using mode, and makes his orher own figure displayed on the screen.

[0062] That is, the image of the human body which is displayed on themonitor 22 has been properly adjusted, but an additional adjustment iscarried out suitably to a certain standard size of the image.

[0063] If the captured image appears on the monitor 22, then the personas a test object selects the timer function which has been provided inthe program menu.

[0064] If the person as a test object is in a passive situation, and ifa separate operator helps the measurement, then the timer function isnot required.

[0065] However, if the person as a test object carries out themeasurement for himself or herself without any assistance of anoperator, then the selection of the timer function has to be necessarilycarried out.

[0066] The reason is as follows. That is, the person as a test objectcannot simultaneously contact his or her hands to the sensors 100 and200 while manipulating the computer. If the timer function is notemployed, then the aura measurement can be carried out only with anassistance of an operator.

[0067] The timer function delays the measurement of the physiologicalsignals for a time period of about 5□10 seconds during which theexecution button is pressed and the two hands are moved to the sensors100 and 200.

[0068] The set time of the timer is not necessarily limited to the abovementioned period, but can be easily varied by those ordinarily skilledin the art.

[0069] If the set time of the timer elapses, then the computer reads thephysiological signals from the hands which have been placed on thesensors 100 and 200. The data thus read is processed by the computer,and the processed results are displayed on the monitor 22 on a real timebasis.

[0070] The image which has been displayed can be outputted to a printer23, and a detailed interpretation can be made to be accompanied to theprinted image, so that the person as a test object can easily understandthe analyzed aura.

[0071] Referring to FIG. 5, the procedure of the operation will bedescribed in detail. First, the person as a test object decides as towhether the camera will be used or not. If the use of the camera isselected, then the relevant computer program is executed to optimize theimage of the person as a test object.

[0072] When the image optimization step is completed, the person as atest object decides as to whether the timer function will be selected ornot through the computer program. If the measurement is carried out foroneself, this step has to be necessarily carried out.

[0073] If the person has selected the use of the timer function, thecomputer delays the reading of the human physiological signals from thesensors for a period of time (about 5□10 seconds) through the relevantprogram.

[0074] Then the timer is driven by manipulating the computer, and then,an operating button is clicked so that the computer would read thephysiological signals of the person from the sensors 100 and 200. Thenthe two hands are placed on the aura sensing part.

[0075] When the set period of the timer elapses, the computer begins toread the physiological signals of the person, and then, analyzes thephysiological signals. Then the analyzed results are displayed on themonitor to show the aura of the person on a real time basis.

[0076] The outputted aura image of the monitor can not only be stored ina form of a file, but also can be outputted to a printer together withan interpretation on it.

[0077] The interpretation of the aura image is stored as a data base inthe form of color and shape. In accordance with the color and shape ofthe aura, diversified interpretations are provided.

[0078]FIG. 5 is a flow chart showing the constitution of the measuringprocedure for the palm-contacting type human body aura measuring systemaccording to the present invention. In this procedure, first therelevant program of the computer is driven, and the computer is put toan initial status (step 300).

[0079] Whether a camera is to be used or not is decided by using theprogram (step 301), and if the camera is to be used, the image of theperson as a test object is optimized (step 302). If it has been decidedthat the camera is not to be used, then this step is skipped.

[0080] The person as a test object decides through the program as towhether the timer function is to be used or not (step 303). If the timerfunction has been selected, then the reading of the physiologicalsignals of the person is delayed for a certain period of time, forinstance, about 5□10 seconds (step 304).

[0081] If an operator is present to assist the measurement, this step isskipped.

[0082] If the set time of the timer elapses, then the system starts toread the physiological signals of the human body from the sensors (step305).

[0083] After reading the physiological signals of the human body fromthe sensors, the aura image of the person is outputted to the monitor(step 306). In accordance with the selection by the person as a testobject, the aura image data is stored in a form of a file, or is printedout together with an interpretation of the aura (step 307).

[0084]FIG. 6 is a block diagram showing the constitution of the footsole-contacting type human body aura measuring system in anotherembodiment of the present invention.

[0085] The two-foot-sole-contacting type human body aura measuringsystem according to the present invention includes: an aura sensing part1 for sensing the physiological signals by being contacted to two footsoles; and a data processing system 2 for processing the sensedphysiological signals.

[0086] The aura sensor part according to the present invention includes:a left foot sole measuring sensor 400; and a right foot sole measuringsensor 500. The right foot sole measuring sensor according to thepresent invention includes: a front foot sole sensor 501 and a rear footsole sensor 502. The left foot sole measuring sensor according to thepresent invention includes: a front foot sole sensor 401 and a rear footsole sensor 402.

[0087] The data processing system includes: a microcomputer 31 forprocessing the measured data; an LCD 32 for outputting the processeddata; an external interface 33 for transmitting the measured data to anexternal apparatus or for receiving an analyzed data from an externalapparatus; and a user button 34 for manipulating the computer system towatch the aura data expression results.

[0088] The foot sole-contacting type aura measuring system can be builtin connection with a body weight scale.

[0089] In this case, the person can stand upon the sensor part, andmanipulate the user buttons to measure the aura. Thus the measured auracan be read through the scale window.

[0090]FIG. 7 is a block diagram showing the constitution of thetwo-finger-contacting type human body aura measuring system in stillanother embodiment of the present invention.

[0091] The two-finger-contacting type human body aura measuring systemin still another embodiment of the present invention includes: an aurasensing part 1 for sensing the physiological signals by being contactedto two fingers; and a data processing system 2 for processing themeasured data.

[0092] The aura sensing part according to the present inventionincludes: a left finger sensor 601 and a right finger sensor 602.

[0093] The data processing system includes: a microcomputer 31 forprocessing the measured data; an LCD 32 for outputting the processeddata; an external interface 33 for transmitting the measured data to anexternal apparatus or for receiving an analyzed data from an externalapparatus; and a user button 34 for manipulating the computer system towatch the aura data expression results.

[0094] The two-finger-contacting type human body aura measuring systemof FIG. 7 in still another embodiment of the present invention can beapplied to a mobile phone. In this case, the two sensors 601 and 602 canbe installed on the cover or main body of the mobile phone, and themeasured results can be read through the LCD window or a computer.

[0095] Further, through the mobile phone, the measured aura can betransmitted to a relevant server, and an interpretation on the measuredaura can be received from the server.

[0096]FIG. 8 is a flow chart showing the constitution of the footsole-contacting type or two-finger-contacting type human body aurameasuring system according to the present invention. FIG. 9 is a flowchart showing the constitution of the measuring procedure for the footsole-contacting type or two-finger-contacting type human body aurameasuring system according to the present invention.

[0097] Referring to FIG. 8, the operating procedure will be described indetail below. First, two fingers are contacted to the respectivesensors.

[0098] Then the physiological signals of the human body are read bymanipulating the user button 34. After a moment, the physiologicalsignals which have been read and processed by the microcomputer 31 areoutputted to the LCD 32 on a real time basis.

[0099] The aura images which are outputted to the LCD can also beoutputted through the external interface 33 to an external printer to beprinted on a paper.

[0100] Referring to FIG. 9, the operating procedure of the presentinvention will be described in detail below. In thetwo-foot-sole-contacting type aura measuring system, the measuringperson can use his or her two hands during the measurement, andtherefore, a time delay is not required.

[0101] Accordingly, if the measuring person starts the measurement bymanipulating the user button 34, then the physiological signals of thehuman body are measured (step 701), and the measured aura is outputtedto the LCD (step 702).

[0102] Specifically, in this embodiment, the present invention includesa data processing system and an aura sensing part.

[0103] Although it is not illustrated in the drawing, a program which iscapable of executing the present invention is installed in the memory ofthe computer.

[0104] The camera, the interface, the user buttons and the printer arethe optional elements, and therefore, they can be properly selected inaccordance with the needs.

[0105] According to the present invention as described above, the systemcan be easily utilized to measure the internal energy state for oneself,and the measured energy state can be confirmed on a real time basisthrough a computer monitor or through an LCD.

[0106] Further, the image of the internal energy state can be analyzedfor oneself without being assisted by a professional person, and thereality sensation of the measured aura image can be improved.

[0107] In the above, the present invention was described based on thespecific preferred embodiments and the attached drawings, but it shouldbe apparent to those ordinarily skilled in the art that various changesand modifications can be added without departing from the spirit andscope of the present invention which will be defined in the appendedclaims.

Want is claimed is:
 1. A system for measuring aura of a human bodycomprising: an aura sensing part to be contacted to two palms, formeasuring the physiological signals of the human body; and a dataprocessing system for processing the aura data of the physiologicalsignals, wherein the data processing system includes a computer forprocessing the obtained data; a monitor and/or a printer for outputtingthe processed data; and a camera for photographing the person as a testobject.
 2. The system for measuring aura of a human body of claim 1wherein said aura sensing part comprises a left hand measuring sensorand a right hand measuring sensor, to be contacted to the palms of thehuman body, wherein the left hand measuring sensor includes a thumbsensor, a first finger sensor, a second finger sensor, a third fingersensor, a fourth finger sensor, an upper palm sensor, an intermediatepalm sensor and a lower palm sensor, for measuring the physiologicalsignals radiating from the fingers and palm, and the right handmeasuring sensor includes a thumb sensor, a first finger sensor, asecond finger sensor, a third finger sensor, a fourth finger sensor, anupper palm sensor, an intermediate palm sensor and a lower palm sensor,for measuring the physiological signals radiating from the fingers andpalm.
 3. A system for measuring aura of a human body comprising: an aurasensing part to be contacted to two feet soles, for measuring thephysiological signals of the human body; and a data processing systemfor processing the aura data of the physiological signals, wherein thedata processing system includes a microcomputer for processing themeasured data; an LCD for outputting the processed data; an externalinterface for transmitting the measured data to an external apparatus orfor receiving an analyzed data from an external apparatus; and a userbutton for manipulating the computer system to watch the aura dataexpression results.
 4. The system for measuring aura of a human body ofclaim 1 wherein said aura sensing part comprises a left foot solemeasuring sensor and a right foot sole measuring sensor, wherein theleft foot sole measuring sensor includes a front foot sole sensor and arear foot sole sensor, and the right foot sole measuring sensor includesa front foot sole sensor and a rear foot sole sensor.
 5. A system formeasuring aura of a human body comprising: an aura sensing part to becontacted to two fingers, for measuring the physiological signals of thehuman body; and a data processing system for processing the aura data ofthe physiological signals, wherein the aura sensing part includes a leftfinger sensor and a right finger sensor, and the data processing systemincludes a microcomputer for processing the measured data; an LCD foroutputting the processed data; an external interface for transmittingthe measured data to an external apparatus or for receiving an analyzeddata from an external apparatus; and a user button for manipulating thecomputer system to watch the aura data expression results.
 6. A methodof measuring aura of a human body comprising: (a) putting the system formeasuring aura of a human body to an initial status by driving theprogram for measuring the aura; (b) contacting two palms on an aurasensing part for measuring physiological signals of a human body; (c)reading the physiological signals of the human body from the sensorswith the system; and (d) displaying the aura image of the physiologicalsignals on a monitor.
 7. The method of measuring aura of a human body ofclaim 6, which further comprises: after step (a), selecting a mode touse a camera for taking a picture of the person tested; and optimizingthe picture image of the person with a computer program.
 8. The methodof measuring aura of a human body of claim 6, which further comprises:after step (a), selecting a mode to use a timer through a program; anddelaying reading of the physiological signals of the person tested forabout 5□10 seconds.
 9. The method of measuring aura of a human body ofclaim 6, which further comprises: storing the displayed aura image in aform of file; and printing the displayed aura image with aninterpretation out with a printer.
 10. A method of measuring aura of ahuman body comprising: (a) putting the system for measuring aura of ahuman body to an initial status by driving the program for measuring theaura; (b) contacting two feet soles on an aura sensing part formeasuring physiological signals of a human body; (c) reading thephysiological signals of the human body from the sensors with thesystem; and (d) displaying the aura image of the physiological signalson a monitor.
 11. A method of measuring aura of a human body comprising:(a) putting the system for measuring aura of a human body to an initialstatus by driving the program for measuring the aura; (b) contacting twofingers on an aura sensing part for measuring physiological signals of ahuman body; (c) reading the physiological signals of the human body fromthe sensors with the system; and (d) displaying the aura image of thephysiological signals on a monitor.